This Month in Blastocystis Research (SEP 2014)

Before leaving for Venice and Padova to introduce Blastocystis to the XXX National Congress of The Italian Society of Protistology (ONLUS), allow me to kick in just a few words for the September issue of 'This Month in Blastocystis Research'.

I will highlight two papers.

The first is a study from the US (Yes, - US data! How rare is that?). The team investigated the prevalence and subtype distribution of Blastocystis among client-owned and shelter-resident cats and dogs. Studies of Blastocystis in companion animals are actually quite rare. The authors used nested PCR for detection, followed by sequencing of PCR products. Interestingly, Blastocystis was not detected in any of the >100 fecal samples from client-owned animals. By comparison, Blastocystis was detected in 10/103 (9.7%) shelter-resident canines, and 12/103 (11.65%) shelter-resident felines. There was no significant difference in Blastocystis spp. carriage rates between the shelter-resident dogs and cats. It is likely that differences in diet and other types of exposure account for Blastocystis being found in shelter-resident animals and not in domestic animals. As for cats and dogs, we don't really know much about what to expect subtype-wise. These animals harboured ST10 mostly, a subtype that has only been found in artiodactyls, NHPs, and lemurs, so far, and - taking these new data into account - with little apparent host preference.

Viktor - an avid fox hunter (in 2007).

Other subtypes included ST1 and one case of ST3, and one case of what was most likely a new subtype - maybe! But then, few animals were positive, and given the different data on subtypes in cats and dogs, it's much too early to speculate on host specific subtypes... for now, it appears that there are none, and that maybe cats and dogs are not really natural hosts? A study by Wang and colleagues identified a plethora of subtypes in dogs: Among 22 positive dogs, most of which were from India, ST1, ST2, ST4, ST5, and ST6 were found. Again, nested PCR was used, and I might have a slight concern that this type of PCR approach is so sensitive that it will pick up the smallest quantity of Blastocystis, maybe even dead Blastocystis or other stages of Blastocystis not necessarily colonising the host (contamination, etc.). But I don't know. The authors of the US study noted that Blastocystis was unlikely to be associated with disease of the animals and were unable to establish a reservoir for human colonisation/infection in these animals.

I never got around to checking Viktor (our cat, pictured above) for Blastocystis. Now it's too late.

I would like to move on to another study. This time the data is from a paper that has just appeared in press in Clinical Gastroenterology and Hepatology. We  analysed faecal DNAs from patients diagnosed with irritable bowel syndrome and healthy individuals. The reason for doing this was due to the fact that intestinal parasite have been speculated to play a role in the development of IBS, a disease affecting about 16% of the adult Danish population. And so we thought that the prevalence of common parasites such as Blastocystis and Dientamoeba fragilis might be higher in IBS patients than in healthy individuals. The study was led by Dr Laura R Krogsgaard, who took a quite unusual approach to collecting questionnaires and faecal samples, namely by collaborating with the company YouGov Zapera.  
We obtained faecal samples from 483 individuals, of whom 186 were cases – ie. patients with IBS – and 297 were healthy controls. DNA was extracted directly from the stool using the easyMag protocol, and the faecal DNAs were submitted to real-time PCR based screening for Blastocystis, Dientamoeba, Entamoeba histolytica and E. dispar, Cryptosporidium, and Giardia.

Above you see the results of the various analyses. Blue columns represent healthy individuals, and orange columns represent IBS patients. Fifty percent of the healthy controls were positive for one or more parasites, while this proportion was significantly lower in IBS patients, 36%. Also for each individual parasite, the number of positive cases was higher among controls than among patients with IBS. Dientamoeba was the most common parasite among healthy controls and IBS patients. In terms of Blastocystis subtypes, the distribution of subtypes between the two groups was non-significant (data not shown).We ended up by concluding that our findings indicated that these parasites are not likely to play a direct role in the pathogenesis of IBS. Longitudinal studies are required to understand their role in gastrointestinal health. 

Still, the role of Blastocystis in human health and disease remains ambiguous, although lots of interesting data is emerging. In order to try and understand the theories behind Blastocystis' potential able to generate disease, I would like to point the readers' attention to a new review, developed by Ivan Wawrzyniak and his prolific colleauges.

Ciao!

References

Krogsgaard LR, Engsbro AL, Stensvold CR, Vedel Nielsen H, & Bytzer P (2014). The Prevalence of Intestinal Parasites is not Greater Among Individuals with IBS: a Population-Based Case-Control Study. Clinical Gastroenterology and Hepatology : the official clinical practice journal of the American Gastroenterological Association PMID: 25229421

Krogsgaard LR, Engsbro AL, & Bytzer P (2013). The epidemiology of irritable bowel syndrome in Denmark. A population-based survey in adults ≤50 years of age. Scandinavian Journal of Gastroenterology, 48 (5), 523-9 PMID: 23506174

Ruaux CG, & Stang BV (2014). Prevalence of Blastocystis in Shelter-Resident and Client-Owned Companion Animals in the US Pacific Northwest. PloS One, 9 (9) PMID: 25226285  

Wang W, Cuttell L, Bielefeldt-Ohmann H, Inpankaew T, Owen H, & Traub RJ (2013). Diversity of Blastocystis subtypes in dogs in different geographical settings. Parasites & Vectors, 6 PMID: 23883734

Wawrzyniak I, Poirier P, Viscogliosi E, Dionigia M, Texier C, Delbac F, & Alaoui HE (2013). Blastocystis, an unrecognized parasite: an overview of pathogenesis and diagnosis. Therapeutic Advances in Infectious Disease, 1 (5), 167-78 PMID: 25165551 

This Month In Blastocystis Research (FEB 2014) - The Protease Edition

A few interesting papers on Blastocystis appeared this month on PubMed. I would like to give a great salute to Ron Fayer's group in Maryland who took to investigating faecal samples and tissue sections from naturally infected pigs. Due to the protease theme of this blog post, I won't go into detail with this paper, but only highlight a few points. The researchers found Blastocystis ST5 in faecal samples from all 11 pigs investigated. By examination of tissue sections they found that Blastocystis existed in the lumen of the jejunum, caecum, proximal and distal colon, but not in the duodenum and ileum. Moreover:

"In tissue sections, Blastocystis was found primarily in the lumen usually associated with digested food debris, sometimes in close proximity or appearing to adhere to the epithelium, but no stages were found to penetrate the epithelium or the lamina propria."

So, the authors did a great job to describe Blastocystis tropism in the pig intestine. It is new to me that the parasite can be found in the jejunum; if anything, I would have thought that the ileum might be 'affected', and certainly the caecum and possibly the remainder of the colon. It is also important to note that in these naturally infected pigs (ST5 is probably the most common subtype in pigs), no signs of invasiveness was detected.

Now, moving on to the proteases, there is a paper out by Arutchelvan Rajamanikam and Suresh K Govind called 'Amoebic forms of Blastocystis spp. - evidence for a pathogenic role'. The study links protease activity to amoebic forms of Blastocystis, which the authors found in symptomatic carriers but not in asymptomatic carriers. Amoeboid forms of Blastocystis being associated with symptomatic infections were described already in 2006 by T C Tan and K G Suresh (whom I believe is identical to S K Govind). While the study is small, investigation of Blastocystis proteases has been going on for a while, and I thought it would be useful to go over some of the literature.

Proteases (or proteinases or peptidases) are enzymes that degrade proteins and therefore useful for instance for the mobilisation and storage of proteins (i.e. 'food'), and the general development and differentiation of cells and tissues, but these enzymes may also be vital for for instance pathogen survival and virulence in the human body (i.e. 'defence' and 'invasion'). Proteases exist in all organisms, i.e. in pro- and eukaryotes + viruses. Proteases are classified on the basis of catalytic mechanism, and five known distinct classes are described: metallo, aspartic, cysteine, serine, and threonine. Being enzymes, proteases digest substrates, can be inhibited, and their functions are dependent on pH and temperature. Hence, proteases can be identified by substrate digestion and by intended inhibition by selective inhibitors (for cystein protease such inhibitors include N-ethylmaleimide, iodoacetamide, and para-hydroxymercuribenzoate for instance).

Turning to the intestinal protozoon Entamoeba for a short while, cysteine proteases have been studied in detail and are among the most likely candidates responsible for the differential pathogenocitiy (virulence factors) of morphologically similar species of Entamoeba: Entamoeba histolytica expresses at least 5 types of cysteine proteases (ACP1, ACP2, ACP3, EhCP5, and EhCP112) and can invade host tissue (leading to amoebiasis), while Entamoeba dispar expresses at least three types of cysteine proteases (EdCP1, EdCP2, and EdCP3) without the ability to invade host tissue. Clinical isolates of E. histolytica release 10- to 1,000-fold more cysteine proteinase activity into the supernatant than E. dispar isolates, although  significant day-to-day variability may be seen. Extracellular cysteine proteases cleave immune secretory IgA (facilitating adhesion of the organism (pathogen) to mucosal surfaces), degrade the extracellular matrix, activate complement, and degrade IgG to circumvent the host immune response. The first evidence of amoebic pathology is local depletion of intestinal mucus and disruption of the epithelial barrier as a result of degradation of the extracellular matrix, which occurs in part from the action of cysteine proteases. More than 80% of patients with amoebiasis develop antibodies against cysteine proteases. Please note that E. histolytica is not consistently invasive; only 10% of E. histolytica infections are believed to be invasive.

Importantly, cysteine proteases are critical to host invasion in a number of parasites. Specific inhibitors block invasion in Trypanosoma cruzi, Plasmodium falciparum, Cryptosporidium parvum, and Toxoplasma gondii.

The main reservoir of Blastocystis ST7 appears to include birds.

Now what do we know about Blastocystis and cysteine proteases? In 2005, Manoj K Puthia from Dr Kevin S W Tan's group in Singapore identified mainly cysteine protease activity in the 'B. hominis B' strain (which is the ST7 strain used in the genome sequencing and annotation study by Denoeud et al. (2011)) and aspartic protease activity in 'B. ratti WR1 strain' (which is a ST4 strain). Lysates and conditioned medium (culture supernatant) from both axenic strain cultures were able to degrade human secretory IgA over 2 h at 37 C, suggesting that Blastocystis actively secrets proteases that - among other things - degrade IgA, thereby potentially evading host mucosal immunity, and enhancing survival opportunities. Along theses lines, in 2006 Sio and colleagues from Tan's group used enzyme digestion (azocasein spectrophotometric assay and gelatin SDS-PAGE analysis), and inhibition assays to characterise proteases from 'B. hominis B' strain. They showed the existence of cysteine proteases with highest activity at neutral pH (the pH of the colon is neutral if even slightly acidic).

Mirza and Tan confirmed that cysteine protease activity was higher in ST7 than in ST4, while inter- and intra-subtype variation in activity was seen over time. In a small study of ST3 positive individuals, Abdel-Hameed and Hassanin were able to detect protease activity in 17/18 symptomatic individuals but only in 2/8 asymptomatic individuals, suggesting intra-subtype differential protease activity. I don't think they tested for protease activity in the culture supernatant.

Cysteine proteases from Blastocystis were reported by Puthia et al. (2008) to enable activation of interleukin 8 (IL-8) gene expression in the human colonic epithelial T84 cell line. IL-8 is a cytokine that attracts PMN and activates monocytes (interestingly, recent results from Olivo-Diaz et al. (2012) suggest that some IL-8 and IL-10 SNPs could change individual susceptibility increasing the relative risk in the development of irritable bowel syndrome (IBS) in Blastocystis carriers).

Gastrointestinal disorders, such as bacterial enteritis, celiac disease, and inflammatory bowel disease, are reported to be associated with a breakdown of epithelial barrier function which is mainly regulated by 'tight junctions'. There is some experimental evidence that Blastocystis may be able to interfere with this regulation and that it may induce host cell apoptosis without attaching to the gut mucosa. Puthia et al. (2006) explain:

"Pathogen invasion and induction of apoptosis are discrete processes, and there are pathogens that can invade but do not induce apoptosis. It appears that induction of apoptosis of host intestinal cells would not be advantageous to a noninvasive parasite like Blastocystis, as it would result in the loss of colonization sites for the parasite. This unintended induction of host cell apoptosis might be a host response against some parasitic factors like proteases which are necessary for the parasite's own life cycle."

Back to the paper by Rajamanikam and Govind: I cannot remember ever seeing amoeboid stages in Blastocystis cultures myself. But then again, in cultures, Blastocystis can take so many forms (some actually resembling the outline of the head of, well, Mickey Mouse (!) and other cuddly creatures (looks like budding off of new cells), and I wouldn't be able to define strict criteria for stratification of organisms into groups. Since we use Jones' Medium also, I do not suspect that it's a 'medium thing'. What we usually see in well-maintained cultures are small, quite inconspicuous and completely spherical cells. Using the aforementioned digestion assays, Rajamanikam and Govind found elevated protease activity related to patient Blastocystis cultures that had a higher percentage of amoebic forms with intense bands representing higher molecular weight proteases (60-100 kDa); the proteases previously described have been of a size of maximum 75 kDa; however, no attempts were made to characterise the proteases in this study. The authors did not include analysis of conditioned medium, and so we do not know whether these proteases were actually secreted. The proteases identified here may be expressed by the amoebic forms only and so they may be responsible for this particular life cycle stage. Knowledge of substrate specificity might have been useful, and it is also possible to actually determine the protein's amino acid sequence and thereby predict it's structure and function using e.g. mass spectrometry (MS) or Edman degradation of peptides.

Just like Ivan Wawrzyniak and colleagues who recently used SDS-PAGE and MS to characterise proteases secreted by the Blastocystis ST7 (B strain). They were able to match two cysteine proteases identified in the culture supernatant to 2 of 22 proteases predicted by in silico analysis of their ST7 B strain genome data, namely Cathepsin B cysteine protease (CBCP) and a Legumain cysteine protease, which the authors speculated to be potentially involved in pathological processes such as mucin degradation. Incidentally, silencing of CBCP has recently been shown to reduce gut penetration in the helminth Faciola hepatica.

Back in 2007, Jésus Serrano-Luna and colleagues studied proteases from pathogenic Naegleria fowleri (causing primary amoebic meningoencephalitis) and non-pathogenic Naegleria gruberi. They observed cysteine proteases in both species, but more proteases in the N. gruberi than in N. fowleri. Protease activity appeared to depend on pH and temp, and moreover, protease patterns for crude extracts and conditioned medium differed

It's probably fair to assume that the expression of potential virulence genes such as genes encoding cysteine proteases may depend on a multiple factors, most of which are yet to be identified, or at least, confirmed. For now, the marked differences in cysteine protease production/expression between and within Blastocystis STs together with experimental evidence highlighting a variation in pathophysiological effects and immunological responses to Blastocystis subtypes isolated from symptomatic and asymptomatic carriers, could be seen as supporting the hypothesis that cysteine proteases may be essential virulence factors responsible for variation in disease symptoms observed across carriers. For more on this, why not look up this paper (free in PubMed Central). However, it is also tempting to think that differential protease expression is merely reflecting various stages in the parasite's life cycle. Things would have been so much easier if we had access to a strain in culture capable of invasion or isolated from an outbreak of Blastocystis infection. But, contrary to parasites of 'acknowledged clinical significance', we do not have such a strain, and neither invasion nor outbreaks of Blastocystis have been reported of, at least not convincingly, I think; please correct me, if I'm wrong. I think it's time for a coffee...

Literature:

Abdel-Hameed DM, & Hassanin OM (2011). Proteaese activity of Blastocystis hominis subtype 3 in symptomatic and asymptomatic patients. Parasitology Research, 109 (2), 321-7 PMID: 21279383

Denoeud F, Roussel M, Noel B, Wawrzyniak I, Da Silva C, Diogon M, Viscogliosi E, Brochier-Armanet C, Couloux A, Poulain J, Segurens B, Anthouard V, Texier C, Blot N, Poirier P, Ng GC, Tan KS, Artiguenave F, Jaillon O, Aury JM, Delbac F, Wincker P, Vivarès CP, & El Alaoui H (2011). Genome sequence of the stramenopile Blastocystis, a human anaerobic parasite. Genome Biology, 12 (3) PMID: 21439036 

Fayer R, Elsasser T, Gould R, Solano G, Urban J Jr, & Santin M (2014). Blastocystis tropism in the pig intestine. Parasitology Research PMID: 24535732

McGonigle L, Mousley A, Marks NJ, Brennan GP, Dalton JP, Spithill TW, Day TA, & Maule AG (2008). The silencing of cysteine proteases in Fasciola hepatica newly excysted juveniles using RNA interference reduces gut penetration. International Journal for Parasitology, 38 (2), 149-55 PMID: 18048044

Mirza H, & Tan KS (2009). Blastocystis exhibits inter- and intra-subtype variation in cysteine protease activity. Parasitology Research, 104 (2), 355-61 PMID: 18846388

Olivo-Diaz A, Romero-Valdovinos M, Gudiño-Ramirez A, Reyes-Gordillo J, Jimenez-Gonzalez DE, Ramirez-Miranda ME, Martinez-Flores WA, Martinez-Hernandez F, Flisser A, & Maravilla P (2012). Findings related to IL-8 and IL-10 gene polymorphisms in a Mexican patient population with irritable bowel syndrome infected with Blastocystis. Parasitology Research, 111 (1), 487-91 PMID: 22287022

Poirier P, Wawrzyniak I, Vivarès CP, Delbac F, & El Alaoui H (2012). New insights into Blastocystis spp.: a potential link with irritable bowel syndrome. PLoS Pathogens, 8 (3) PMID: 22438803

Puthia MK, Vaithilingam A, Lu J, & Tan KS (2005). Degradation of human secretory immunoglobulin A by Blastocystis. Parasitology Research, 97 (5), 386-9 PMID: 16151742

Puthia MK, Sio SW, Lu J, & Tan KS (2006). Blastocystis ratti induces contact-independent apoptosis, F-actin rearrangement, and barrier function disruption in IEC-6 cells. Infection and Immunity, 74 (7), 4114-23 PMID: 16790785

Que X, & Reed S L (2000). Cysteine Proteinases and the Pathogenesis of Amebiasis. Clinical Microbiology Reviews, 13 (2), 196-206 DOI: 10.1128/CMR.13.2.196-206.2000

Rajamanikam A, & Govind SK (2013). Amoebic forms of Blastocystis spp. - evidence for a pathogenic role. Parasites & Vectors, 6 (1) PMID: 24499467

Serrano-Luna J, Cervantes-Sandoval I, Tsutsumi V, & Shibayama M (2007). A biochemical comparison of proteases from pathogenic Naegleria fowleri and non-pathogenic Naegleria gruberi. The Journal of Eukaryotic Microbiology, 54 (5), 411-7 PMID: 17910685

Sio SW, Puthia MK, Lee AS, Lu J, & Tan KS (2006). Protease activity of Blastocystis hominis. Parasitology Research, 99 (2), 126-30 PMID: 16518611 

Wawrzyniak I, Texier C, Poirier P, Viscogliosi E, Tan KS, Delbac F, & El Alaoui H (2012). Characterization of two cysteine proteases secreted by Blastocystis ST7, a human intestinal parasite. Parasitology International, 61 (3), 437-42 PMID: 22402106 

Do IBS Patients Lack Blastocystis and Dientamoeba??

I feel like sharing data from a poster created by one of my colleagues, Dr Laura Rindom Krogsgaard who works at Køge Sygehus, Denmark. She presented the poster last month at the United European Gastrointestinal (UEG) Week in Berlin.

Laura is currently doing a very interesting survey on IBS and IBS-like symptoms in Danish individuals. Her first publication was on the epidemiology of IBS in Denmark (see literature list below). She performed a web-based survey, using YouGov Zapera, and questionnaires were emailed to a web panel (n = 19,567) representative of the general Danish population aged 18-50 years containing info on gender, age, geography and type of intestinal symptoms (if any). IBS and subtypes were estimated by the Rome III criteria. Of 6,112 responders, 979 (16%) fulfilled the Rome III criteria for IBS and had no organic diagnosis likely to explain their symptoms. IBS subtypes detected included  mixed IBS (36%), IBS with diarrhea (33%), IBS with constipation (18%), and unsubtyped IBS (11%).

At the Laboratory of Parasitology, we helped Laura analyse stool samples from survey participants for parasites. Not surprisingly, Blastocystis and Dientamoeba were by far the most common parasites detected; however, it appeared that individuals with IBS symptoms were less likely to be colonised by these parasites than their controls! Which means that we have a situation reminiscent of that seen in IBD patients, only less pronounced. 

Laura was able to survey symptom developement over 1 year and compare this to the incidence of Blastocystis and Dientamoeba, and none of the parasites (indvidually or in co-infection) were linked to symptom development.

Indeed, Laura's data are in line with the general tendency that we see for Blastocystis (see figure below). Blastocystis appears to be rare in individuals with perturbation of the intestinal microbiota (due to antibiotic treatment, inflammation, infection, diet, etc.), while common in healthy individuals, most of whom are probably characterised by high gut microbial diversity and thereby - apparently - the right substrate/growth conditions for Blastocystis.

Literature:

Krogsgaard LR, Engsbro AL, & Bytzer P (2013). The epidemiology of irritable bowel syndrome in Denmark. A population-based survey in adults ≤50 years of age. Scandinavian Journal of Gastroenterology, 48 (5), 523-9 PMID: 23506174

The entire poster "Dientamoeba fragilis and Blastocystis: Two parasites the irritable bowel might be missing" presented at the UEGweek can be viewed here via SlideShare.

Dying to know about Dientamoeba?

It's difficult to say 'Blastocystis' without saying 'Dientamoeba fragilis'. Both parasites tend to be extremely common in countries where other intestinal parasites (e.g. Entamoeba, Giardia, Cryptosporidium) are of low endemic occurrence, and they are often seen together in patient samples. It is only due to the recent introduction of DNA-based diagnostic methods (PCR) that we now know that these parasites are much more common than previously anticipated.

So, while I'm trying to encourage guest bloggers, I thought I'd introduce a 'guest star' - Dientamoeba!

Dientamoeba fragilis trophozoites with the characteristic binucleated feature.

The parasite belongs to the trichomonads, which also comprise parasites such as Histomonas meleagridis (the cause of 'blackhead disease' in turkeys) and - more distantly - Trichomonas vaginalis.

At our Parasitology Lab at Statens Serum Institut in Copenhagen we have been using real-time PCR for specific detection of Dientamoeba fragilis in faecal samples from patients with gastrointestinal symptoms for quite a few years now. In the period of 2008-2011 we analysed 22,484 stool samples for D. fragilis. The overall prevalence of the parasite in these samples was 43% but depended mainly on age (Figure 1). D. fragilis prevalence appears to fluctuate dramatically depending on the age group. Highest prevalence was seen among 7-year-olds, and a second 'peak' is seen in the parental age suggesting that infected children pass on infections to their parents. 

Figure 1:  Prevalence of D. fragilis as a function of age. (For more information, see Röser et al., 2013b).

Intestinal protozoa are transmitted faecal-orally and most of them have a cyst stage. However, a few protozoa appear not to have a cyst stage, among them D. fragilis. There is a lot of evidence that Histomonas meleagridis is transmitted by eggs of Heterakis gallinae, a nematode of galliform birds. Conspicuously, we recently demonstrated the presence of D. fragilis DNA in surface-sterilised eggs of Enterobius vermicularis (pinworm). The implications of this finding are unclear but could suggest a similar vector-borne transmission of D. fragilis.

As in so many other situations it is not possible to dish out simple guidelines as to when to test for and treat D. fragilis. It is clear that many carriers experience few or no symptoms at all, but there are several case reports demonstrating symptom relief in patients eradicated of D. fragilis. We published one such case recently in 'Ugeskrift for Læger' - the journal of the Danish Medical Association. Basically, the report describes lasting symptom relief after documented eradication of D. fragilis using high dose metronidazole. However, the patient's symptoms returned after a year, and  real-time PCR revealed D. fragilis positive stools. Eradication was achieved using paromomycin (250 mg x 3 for nine days).

Contrary to Blastocystis, this parasite exhibits remarkably limited genetic diversity. We recently analysed three different genetic loci (18S, actin, elongation factor 1-alpha), and we confirmed that only 2 genotypes exist, one of which is very rare. Genetically, however, the two genotypes are quite different, and it will be interesting to compare the nuclear genomes of the two, once they have become available.

Dientamoeba has been speculated to be a neglected cause/differential diagnosis of irritable bowel syndrome (IBS). We once found a statistical significant association between IBS and Dientamoeba; however, other more recent and more targeted studies (one of which is ongoing) have not confirmed this association. However, multiple factors could interact and analysing only simple associations such as symptoms related to parasite presence/absence may be a limiting approach; for instance, infection load/intensity may play a role, and other factors such as host genetics/susceptibility and microbiota ecology may be significant factors influencing on clinical outcome as well. On that note, we have observed some very low Ct values in our real-time PCR results for some of our D. fragilis positive patients, suggesting massive infections. D. fragilis infections are probably often long lasting (months), and if symptoms appear in the initial phase of infection only, cross-sectional studies of prevalence and clinical presentation will be potentially misleading. Large longitudinal cohort studies of pre-school children with monitoring of incidence of pinworm and D. fragilis infections would be extremely informative.

Dr Dennis Röser here at the SSI is currently finishing a randomised controlled treatment trial of D. fragilis in children, testing the clinical efficacy of metronidazole treatment versus placebo. Results are expected next year, so watch out for a 'D. fragilis special' by Dr Röser in 2014! It appears a lot easier to eradicate D. fragilis than Blastocystis - at least on a short term basis with metronidazole having an efficacy of about 70% or so (unconfirmed).

A couple of reviews free for download are available; please see literature list below or go here and here.

Suggested literature

Engsbro AL, Stensvold CR, Nielsen HV, & Bytzer P (2012). Treatment of Dientamoeba fragilis in patients with irritable bowel syndrome. The American Journal of Tropical Medicine and Hygiene, 87 (6), 1046-52 PMID: 23091195   

Johnson EH, Windsor JJ, & Clark CG (2004). Emerging from obscurity: biological, clinical, and diagnostic aspects of Dientamoeba fragilis. Clinical Microbiology Reviews, 17 (3) PMID: 15258093

Ogren J, Dienus O, Löfgren S, Iveroth P, & Matussek A (2013). Dientamoeba fragilis DNA detection in Enterobius vermicularis eggs. Pathogens and Disease PMID: 23893951  

Röser D, Nejsum P, Carlsgart AJ, Nielsen HV, & Stensvold CR (2013a). DNA of Dientamoeba fragilis detected within surface-sterilized eggs of Enterobius vermicularis. Experimental Parasitology, 133 (1), 57-61 PMID: 23116599   

Röser D, Simonsen J, Nielsen HV, Stensvold CR, & Mølbak K (2013b). Dientamoeba fragilis in Denmark: epidemiological experience derived from four years of routine real-time PCR. European Journal of Clinical Microbiology & Infectious Diseases : official publication of the European Society of Clinical Microbiology, 32 (10), 1303-10 PMID: 23609513  

Stark DJ, Beebe N, Marriott D, Ellis JT, & Harkness J (2006). Dientamoebiasis: clinical importance and recent advances. Trends in Parasitology, 22 (2), 92-6 PMID: 16380293  

Stark D, Barratt J, Roberts T, Marriott D, Harkness J, & Ellis J (2010). A review of the clinical presentation of dientamoebiasis. The American Journal of Tropical Medicine and Hygiene, 82 (4), 614-9 PMID: 20348509

Stensvold CR, Clark CG, & Röser D (2013). Limited intra-genetic diversity in Dientamoeba fragilis housekeeping genes. Infection, Genetics and Evolution : journal of molecular epidemiology and evolutionary genetics in infectious diseases, 18, 284-6 PMID: 23681023

Stensvold CR, Lewis HC, Hammerum AM, Porsbo LJ, Nielsen SS, Olsen KE, Arendrup MC, Nielsen HV, & Mølbak K (2009). Blastocystis: unravelling potential risk factors and clinical significance of a common but neglected parasite. Epidemiology and infection, 137 (11), 1655-63 PMID: 19393117

This Month In Blastocystis Research (AUG 2013)

Quite a few papers relevant to Blastocystis research have made it to PubMed over the past month! Therefore, the August version of 'This Month in Blastocystis Research' is more like a list of papers + short descriptions/comments, rather than one or two actual paper reviews.

Dr Aldert Bart and his Dutch colleagues have published a study that confirms data emerging from other parts of Europe. Using microscopy (fixed faecal smears) and PCR, they found an almost 40% prevalence of Blastocystis in returning travelers with symptoms, and a prevalence of 18% in patients referred for other reasons. The distribution of subtypes found in the study population was quite similar to what has been found elsewhere in Europe with ST3 predominating (42%) and the rest of the subtypes attributable to ST1 (22%), ST2 (22%), ST4 (12%), ST6 (1%) and ST7 (1%).

The Tropical Parasitology theme issue on Blastocystis has now gone live. You’ll find a link to the editorial and the three papers included in the symposium here.

In my previous post I referred to a new study from Colombia which includes subtyping of Blastocystis isolates from humans, and a variety of animals, including birds. The paper is interesting for a number of reasons, but first and foremost it confirms the virtual absence of ST4 in humans in S America. Moreover, the study included 70 Blastocystis positive samples from asymptomatic carriers, 40 positive samples from patients with diarrhoea, and 15 positive samples form patients with IBS. Remarkably, all samples from healthy carriers were typed as ST1, those from patients with diarrhoea belonged to ST2, and those from IBS patients to ST3. Such a clear-cut distribution of subtypes across cohorts is unprecedented and of course warrants confirmation and further investigation. In Europe, ST4 is very common in humans, while it appears rare in humans in many other parts of the world. ST4 also appears rare among non-human primates (NHPs), our closest living relatives, and while NPHs and humans otherwise tend to share the same major subtypes (ST1, ST2, and ST3), this suggests that while subtypes 1, 2 and 3 have probably co-evolved with primates, ST4 has only recently entered the primate population with a preference for humans! I have hinted at this many times by now, but I find it extremely interesting which is why I keep repeating it.

There is a paper out by Santos and Rivera from the Philippines comparing microscopy of direct faecal smear with culture and PCR for detection of Blastocystis. They ended up concluding that culture was the best diagnostic modality, but it should be noted that the PCR used in the study targets a 1.8 kbp product (complete SSU rRNA gene!), and much smaller products are usually targeted in diagnostic PCR assays. The Blastocystis real-time PCR developed by me and my colleagues targets a sequence stretch of ~120 bp, securing optimum test sensitivity. The results of the Philippine study should be interpreted with this in mind.

Li et al., have published data on experimental infection of ST1 in Sprague-Dawley rats. Animals belonging to this species appeared susceptible to a ST1 strain isolated from a diarrhoeic patient that had been kept in culture and for which induction of cysts had been performed with a view to infecting the rats. The study confirms that Blastocystis is mainly a parasite of the coecum and colon. The authors found evidence of Blastocystis invasion into the lamina propria in one of the animals, and signs of inflammation in all animals challenged. While it is great to see that experimental models can be sustained and that encystation can be induced in vitro, at least two important factors must be kept in mind to fully comprehend the study: Although cysts were isolated by gradient centrifugation prior to inoculation, it is unlikely that all bacteria have been removed from cyst suspensions; in other words, the cyst preparation is not likely to be 'sterile', and any effect of the potentially accompanying bacterial flora is difficult to determine. Moreover, rats may not be natural hosts of ST1 (very few data available on the topic!), and so, the pathology caused in the rats may be an unlikely finding in humans, who are indeed natural hosts of ST1 and may have developed a high degree of tolerance to this subtype.

Are dogs, wolves, and other canids natural hosts of Blastocystis?

When visiting Australia earlier this month, I had the pleasure of meeting Wenqi Wang and Tawin Inpankaew, both PhD students working at School of Veterinary Science, The University of Queensland Gatton Campus and supervised by Dr Rebecca Traub. One of the foci of this group is to study Blastocystis in animals, for instance in households where animals are kept as pets. Recently, a paper emerged from this group on diversity of Blastocystis subtypes in dogs in different geographical settings, hence domestic/pound dogs from Brisbane, Australia, semi-domesticated dogs from a village in Cambodia, and stray dogs from Mumbai and other Indian cities. Using sensitive PCR methods they observed that almost one fourth of the Indian dogs were infected, while dogs in the Cambodian village and in Queensland remained largely uninfected. Coprophagy and access to Blastocystis-positive stool from different hosts may account for the relatively high prevalence in stray dogs in India, although one might assume that the prevalence would then be even much higher? The team used nested PCR in their study and found four different subtypes in the Indian dogs, including ST1, ST4, ST5 and ST6. Whether all of their data collectively indicate that dogs are not natural hosts of Blastocystis is a matter of debate and remains to be more thoroughly investigated. Indeed, prevalence and subtype data from studies of samples from wild life canids (dingos, jackals, wolves, coyotes, but also foxes and raccoon dogs) would shed further light on this topic.

Finally, for those interested in how Blastocystis deals with oxidative stress and related metabolic issues, there is a paper out on iron-sulphur cluster biogenesis in protozoan parasites by Ali and Nozaki citing works by Tsaousis (2012), Denoeud (2011), Long (2011), and Stechmann (2008).

Literature:

Ali V, & Nozaki T (2013). Iron-sulphur clusters, their biosynthesis, and biological functions in protozoan parasites. Advances in Parasitology, 83, 1-92 PMID: 23876871

Bart A, Wentink-Bonnema EM, Gilis H, Verhaar N, Wassenaar CJ, van Vugt M, Goorhuis A, van Gool T. Diagnosis and subtype analysis of Blastocystis sp. in patients in a hospital setting in the Netherlands. BMC Infectious Diseases, 13:289.

Li J, Deng T, Li X, Cao G, Li X, & Yan Y (2013). A rat model to study Blastocytis subtype 1 infections. Parasitology Research PMID: 23892480 DOI: 10.1007/s00436-013-3536-7

Parija SC (2013). Blastocystis: Status of its pathogenicity. Tropical Parasitology, 3 (1) PMID: 23961433

Parija SC, & Jeremiah S (2013). Blastocystis: Taxonomy, biology and virulence. Tropical Parasitology, 3 (1), 17-25 PMID: 23961437 

Ramírez JD, Sánchez LV, Bautista DC, Corredor AF, Flórez AC, & Stensvold CR (2013). Blastocystis subtypes detected in humans and animals from Colombia. Infection, Genetics and Evolution : Journal of Molecular Epidemiology and Evolutionary Genetics in Infectious Diseases PMID: 23886615

Sekar U, & Shanthi M (2013). Blastocystis: Consensus of treatment and controversies. Tropical Parasitology, 3 (1), 35-9 PMID: 23961439

Stensvold CR (2013). Blastocystis: Genetic diversity and molecular methods for diagnosis and epidemiology. Tropical Parasitology, 3 (1), 26-34 PMID: 23961438  

Wang W, Cuttell L, Bielefeldt-Ohmann H, Inpankaew T, Owen H, & Traub RJ (2013). Diversity of Blastocystis subtypes in dogs in different geographical settings. Parasites & Vectors, 6 PMID: 23883734